KR20170092051A - Relay - Google Patents

Abstract

The present invention relates to a relay capable of preventing a chattering phenomenon and fundamentally eliminating an unbalance problem when coming in contact with a contact. The relay according to the present invention comprises: a fixed contact having a first fixed contact and a second fixed contact; a movable contact movable to a first position contacting the first fixed contact and a second position separated from the first fixed contact; a conductive connector always electrically connecting the movable contact and the second fixed contact; and a driving mechanism providing driving force to move the movable contact to the first position or the second position.

Description

Relay {RELAY}

The present invention relates to a relay, and more particularly to a relay having a single movable contact with one movable contact for two fixed electrodes.

In an electric vehicle, a battery disconnection unit is used for control to supply or cut off electric power from the battery to the inverter.

These battery disconnect units include two main relays for the two DC power supply paths, positive and negative, and one precharge relay for protecting the main relay from the initial inrush current.

The precharge relay temporarily turns on an initial inrush current generated when the electric vehicle is started to protect the main relay from the initial inrush current.

As an embodiment of the present invention, the present invention can be applied to such pre-charge relays, but the present invention can be applied to various kinds of relays.

In this relay, the prior art will be described with reference to Figs. 1 to 9. Fig.

1, the outer shape of the relay 100 according to the related art has a rectangular parallelepiped shape and is connected to a main circuit which has a portion protruding from the upper side in the drawing and exposed to the front and supplying DC power A control signal receiving terminal 2 having main circuit terminals 1 and a portion protruding from the bottom toward the front to receive an open / close control signal (also called an excitation control signal) of the relay 100, . Here, the opening / closing control signal (also called an excitation control signal) may be provided as a voltage signal of DC 12 volts, for example.

1, reference numeral 50 designates an enclosure for accommodating the components of the relay 100 according to the prior art.

The outline of the relay according to the present invention may be the same as or similar to the relay according to FIG. 1 described above and shown in FIG. 1, so that the external appearance of the relay according to the present invention will be omitted.

The internal structure of the relay 100 according to the related art will be described with reference to FIGS. 2 to 6. FIG.

The relay 100 according to the related art includes an upper mechanism assembly 20, a movable unit assembly 30, a magnetic coil assembly 40, An enclosure 50, and a lower cover 60, as shown in FIG.

The upper mechanism assembly 20 includes a main circuit terminal 1, a stationary contact 3, a ferrite magnet 12, a return spring 13, An upper cover 21, an insulating support, and the like.

3 shows the upper mechanism assembly 20 in an upside down fashion to show the structure of the upper mechanism assembly 20. When assembled, the upper mechanism assembly 20 has an attitude as shown in FIG.

3, the main circuit terminal 1 has a thin rod-like conductor portion which is not visible due to the insulating supports but extends beyond the upper cover 21 to the inside of the relay 100 to the stationary contact 3, 3 is a part of the conductor portion, which is shown at the bottom of the stationary contact 3.

The fixed contact 3 includes one fixed contact connected to the positive electrode side main circuit terminal 1 and another fixed contact connected to the negative electrode side main circuit terminal 1, Are welded to the contact portions of the circuit terminals 1, respectively.

The strong magnet 12 is constituted by a permanent magnet having a strong magnetic property and an arc generated when the stationary contact 3 and the movable contact 4 are separated from each other in a contact state is fixed by a magnetic flux generated around the stationary contact 3 And one on each of the left and right sides of the pair of stationary contacts 3 for arc extinguishing by guiding them to the side of the movable contact 4.

One end of the return spring 13 is supported by the insulation supporting portion between the pair of fixed contacts 3 and the other end is supported by a recess formed in the upper end of the movable unit assembly 30, In the direction away from the stationary contact (3). Therefore, when the coil (see reference numeral 6 in FIG. 2 or 5) of the excitation coil assembly 40 is demagnetized, the movable assembly 30 is returned to the initial position spaced apart from the fixed contact 3.

The upper cover 21 is a cover part that shields the internal components of the relay 100 from the outside and includes a lower cover 60 for shielding the excitation coil assembly 40 located below the relay 100 from the outside, And otherwise shields the upper mechanism assembly 20 and the movable unit assembly 30 located at the upper and middle portions of the precharge relay 100 from the outside.

The insulator support portion electrically insulates and supports the extended portion of the precharge relay 100 of the main circuit terminal 1 with the rigid magnet 12 and the return spring 13 and the like, And may be made of a synthetic resin material.

The movable part assembly 30 includes a shaft 5, a movable contact arm 4a, a contact spring 7 and a movable core 10 as shown in Fig. .

The shaft 5 may be formed of an electrically insulating material as a cylindrical member including an upper large diameter portion having a large diameter and a lower small diameter portion having a smaller diameter than the upper portion.

The upper portion of the shaft 5 has a hollow portion at the lower end of the recess portion for receiving the contact spring 7, And an opening formed in the front-rear direction so as to allow penetration insertion of the movable contactor 4a and formed to be opened by a predetermined length in the vertical direction.

The lower small diameter portion of the shaft (5) has a predetermined outer diameter that can be press-fitted into the inner diameter portion of the movable core (10).

The shaft 5 and the movable core 10 can be engaged with each other by press fitting the lower small diameter portion of the shaft 5 into the inner diameter portion of the movable core 10 and the shaft 5 and the movable core 10 10 can move in the same direction together.

The movable contact 4a is formed of a conductive metal plate such as copper and is inserted through the opening of the shaft 5 as shown in Fig. 4, and the longitudinal center portion of the movable contact 4a is connected to the lower contact pressure And is urged upward by the spring 7 in contact with the upper portion of the opening portion.

The movable contacts 4 are welded to the upper surfaces of the longitudinally opposite ends of the movable contactor 4a.

The contact spring 7 is provided as a compression spring in the hollow portion of the shaft 5 and in particular the upper end of the contact spring 7 supports the longitudinal center portion of the movable contact 4a, Is supported by the hollow bottom surface of the shaft (5).

Therefore, the contact spring 7 can be compressed or unfolded in the hollow portion of the shaft 5. [

The movable core 10 may be formed of a hollow cylindrical iron core.

As shown in FIG. 2 or FIG. 7, a rubber pad 11 is press-fitted into the movable core 10 at the lower end of the movable core 10 to be coupled with the movable core 10.

The rubber pad 11 is wound on the inner bottom surface of the enclosure 50 when the movable core 10 is returned to its original lowered position by the return spring 13 in the element of the excitation coil assembly 40 It is provided to alleviate noise and shock.

The movable core 10 and the shaft 5 are coupled by press-fitting the lower small diameter portion of the shaft 5 into the hollow portion of the movable core 10.

The movable core 10 is magnetized by a magnetic field from the excitation coil assembly 40 and raised against the vertical magnetic field applied from the excitation coil assembly 40 or the excitation coil assembly 40 is demagnetized And is lowered by the elastic force of the return spring 13 which acts on the upper end of the shaft 5.

The excitation coil assembly 40 is configured to include a bobbin 8, a coil 6, a yoke 9 and a control signal receiving terminal 2 as can be seen in Fig.

The bobbin 8 has a hollow cylindrical body portion which is hollow to allow the movable core 10 to enter or leave the body 10 and a flange FLANGE formed at the upper and lower ends of the body portion to determine a winding limit of the coil 6, And a coil 6 is wound on the body portion.

The coil 6 is wound on the body portion of the bobbin 8 and excited or magnetized depending on whether a control signal is applied to the control signal receiving terminal 2 or not.

The yoke 9 is formed to surround the outside of the bobbin 8 as best seen in Fig. 2 and provides a path through which the magnetic flux generated by the coil 6 circulates when the coil 6 is energized.

2 and 5, the control signal receiving terminal 2 is provided so as to penetrate through the coil 6 wound around the control signal receiving terminal 2. When receiving the control signal through the control signal receiving terminal 2, The coil 6 is excited, and when the control signal is stopped, the coil 6 is excited.

1, 2, or 6, the enclosure 50 provides a means for housing the components of the precharge relay 100, and is formed of a synthetic resin material having electrical insulation. 6, the enclosure 50 may be formed of a rectangular parallelepiped member having one side open and an interior empty and the remaining five sides clogged to accommodate the components.

6, the lower cover 60 is a lid portion that shields the internal components of the relay 100 from the outside, and includes an upper mechanism assembly 20 located at the upper portion and a middle portion of the relay 100, Unlike the upper cover 21 which shields the assembly 30 from the outside, the excitation coil assembly 40 located below the relay 100 is shielded from the outside.

The lower cover 60 has two through-holes correspondingly formed to allow penetration for exposure of the control signal receiving terminal 2.

The operation of the relay 100 according to the related art constructed as described above will be briefly described.

When the control signal is applied through the control signal receiving terminal 2 in the OFF state of the relay 100 as shown in FIG. 2, the coil 6 is excited and the vertical magnetic field The movable core 10 is also energized and raised.

The movable contact 4a supported by the shaft 5 and the contact spring 7 can be prevented from rotating relative to the shaft 5 while the shaft 5 having the lower end coupled to the movable core 10 overcomes the elastic force of the return spring 13 Rise.

The movable contact 4 welded to the upper ends of both ends of the movable contact 4a rises and comes into an ON state in which it contacts the corresponding pair of fixed contacts 3, Respectively.

Then, as a closed circuit is formed from the positive main circuit terminal 1 to the fixed contact 3, the movable contact 4, the movable contact 4a, the fixed contact 3 and the negative main circuit terminal 1 A current path from the positive main circuit terminal 1 to the negative main circuit terminal 1 is formed and the DC power can be supplied through the relay 100. [

7, when the application of the control signal through the control signal receiving terminal 2 is stopped, the vertical magnetic field imposed from the coil 6 is removed while the coil 6 is disengaged, and the movable core 10 are also disengaged, the lifting force of the movable core 10 disappears.

The shaft 5 is lowered by the elastic force of the return spring 13 acting on the upper end portion of the shaft 5 and the movable contact 4a supported by the shaft 5 and the contact spring 7 is also lowered do.

Therefore, the both movable contacts 4 welded to the upper ends of the both ends of the movable contactor 4a are lowered and turned off from the corresponding pair of fixed contacts 3, Respectively.

Then, the energizing path from the positive main circuit terminal 1 to the negative main circuit terminal 1 is interrupted, and the DC power is stopped from being supplied through the relay 100. [

On the other hand, the electromagnetic repulsive force generated around the contact point at the initial stage of the ON operation will be described with reference to FIG.

The current flowing through the fixed contact 3 (see the left side in FIG. 8) connected to the positive main circuit terminal as shown in FIG. 8 is transmitted through the movable contact 4a again to the fixed contact 3 The electromagnetic repulsive force (electromagnetic force) pushing the movable contact 4a out of the stationary contact 4a is reversed because the direction of the inflow current I1 (downward) and the direction of the excitation current I2 repulsive force, see down arrow F in Fig. 8) occurs between the contacts.

The arc generated between the movable contactor 4a and the stationary contact 3 by the magnetic field B from the strong magnet 12 is subjected to a force pushing it outward like the forces F1 and F2.

Therefore, as can be seen from the dotted circle A in FIG. 9, a CHATTERING phenomenon occurs in which the movable contact in the initial state of the ON operation contacts the fixed contact and is disconnected rapidly.

Since the original precharge relay is a means for bypassing the initial inrush current at the start of the electric vehicle, such chattering will delay the time for bypassing the initial inrush current, so that the main relay of the battery disconnect unit is inrush current And shorten the service life thereof.

2 and 7, the precharge relay according to the prior art is in a state in which only the central portion of the movable contact 4a is supported by the contact pressure spring 7, so that the two movable contacts 4, The contact between the movable contact 4 and the stationary contact 3 is worn out with a lapse of time so that the contact between the movable contact 4 and the stationary contact 3 is worn out. There is a problem that the basic performance of the charge relay (initial inrush current bypass function) is adversely affected.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a relay capable of preventing a chattering phenomenon and fundamentally eliminating an unbalance problem at the time of contact.

It is an object of the present invention to provide a relay,

A fixed contact having a first fixed contact and a second fixed contact;

A movable contact movable into a first position contacting the first stationary contact and a second position separated from the first stationary contact;

A conductive connector for electrically connecting the movable contact and the second fixed contact at all times; And

And a driving mechanism for providing a driving force to the movable contact to move to the first position or the second position.

According to a preferred aspect of the present invention, the movable contact is composed of a single contact.

According to another preferred embodiment of the present invention, the conductive connector is composed of a flexible cable which has one end connected to the movable contact and the other end connected to the second fixed contact.

According to another preferred embodiment of the present invention, the relay according to the present invention further includes a permanent magnet which is not installed around the second stationary contact but installed only around the first stationary contact to protect the contact from the arc.

According to another preferred aspect of the present invention, the drive mechanism includes: a coil assembly including a coil that provides a driving force to move the movable contact in a first position when magnetized; A stationary core fixedly installed in the coil assembly; A shaft that is coaxial with the movable contact and supports the movable contact and is movable together with the movable contact; A contact spring having one end contacting the movable contact so as to apply an elastic force to the movable contact in a direction in contact with the fixed contact; And a movable core connected to a lower portion of the shaft and movable to a position where the movable core approaches the fixed core according to magnetization or demagnetization of the coil and a position separated from the fixed core.

According to another preferred aspect of the present invention, the shaft is coupled to the movable contact so as to support the movable contact without flow.

According to another preferred aspect of the present invention, the relay according to the present invention is provided between the fixed core and the movable core so as to be inserted into the inner diameter portion of either the fixed core or the movable core, And a return spring for applying an elastic force in a direction separating from the fixed core.

Since the relay according to the present invention includes the conductive connector that always electrically connects the movable contact to any one of the fixed contacts, the electromagnetic repulsion force is reduced and the occurrence of the chattering phenomenon is significantly reduced in the closing operation Can provide an effect.

In the relay according to the present invention, since the movable contact is constituted by a single contact point, it is possible to fundamentally prevent the phenomenon that only one of the contacts contacts in a biased manner or is unevenly worn by the contact, thereby improving the operational reliability of the precharge relay And the contact life can be prolonged.

In the relay according to the present invention, since the conductive connector is constituted by a connecting wire having one end connected to the movable contact and the other end connected to the second stationary contact, it is possible to flexibly move the movable contact It is possible to provide an excellent mechanical durability while being expanded and contracted, and also to provide an excellent function as a current carrying path.

The relay according to the present invention includes a permanent magnet which is not installed around the second stationary contact but installed only around the first stationary contact to protect the contact from the arc, It is possible to reduce the number of permanent magnets to be installed in comparison with the technology, thereby reducing the manufacturing cost of the precharge relay compared to the prior art.

In the relay according to the present invention, the drive mechanism includes a shaft which is coaxial with the movable contact and supports the movable contact and is movable together with the movable contact, so that the shaft of the movable contact and the shaft The transmission of the driving force for moving the movable contact can provide a certain effect.

In the precharge relay according to the present invention, since the shaft is coupled to the movable contact, the contact position with the stationary contact can be made constant as compared with the prior art in which the movable contact can flow.

The relay according to the present invention further includes a return spring inserted between the fixed core and the movable core so as to be inserted into the inner diameter portion of any one of the fixed core and the movable core, And the return spring can be stably held in the inner diameter portion of either the fixed core or the movable core without being displaced.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an external perspective view showing the outline of a relay according to the prior art or the present invention,
2 is a longitudinal sectional view showing an internal configuration of a relay according to the prior art and showing an off state,
3 is a perspective view showing a configuration of an upper mechanism assembly among relays according to the related art,
4 is a perspective view showing a configuration of a moving part assembly of a relay according to the related art,
5 is a perspective view showing a configuration of an excitation coil assembly of relays according to the related art,
Fig. 6 is a perspective view of a disassembly of a relay according to the prior art,
FIG. 7 is a longitudinal sectional view showing the ON state of the relay according to the prior art,
FIG. 8 is an explanatory diagram for explaining the phenomenon of generation of an electron repulsion force according to the direction of the inflow current and the outflow current in the relay according to the related art,
9 is a waveform chart showing a chattering phenomenon due to an electromagnetic repulsion force in a relay according to the related art,
10 is a vertical cross-sectional view showing an internal configuration of a relay according to a preferred embodiment of the present invention and showing an off state,
11 is a perspective view showing a configuration of an upper mechanism assembly among relays according to a preferred embodiment of the present invention,
12 is an exploded perspective view of a drive mechanism showing the structure of a drive mechanism among relays according to a preferred embodiment of the present invention,
13 is a perspective view showing a configuration of an excitation coil assembly of a relay according to a preferred embodiment of the present invention,
FIG. 14 is a perspective view of a principal part of a relay according to a preferred embodiment of the present invention,
15 is a vertical cross-sectional view showing the on-state of the relay according to the present invention,
16 is an explanatory view clearly showing a reason for reducing the electron repelling force in the relay according to the present invention,
17 is a waveform chart showing a chattering phenomenon due to an electromagnetic repulsive force in the relay according to the present invention, compared to the prior art.

The above and other objects, features and advantages of the present invention will become more apparent from the following description of the preferred embodiments of the present invention with reference to the accompanying drawings.

14, the relay 100 according to the preferred embodiment of the present invention roughly includes an upper mechanism assembly 20, a shaft assembly 30-1, a conductive connector 14, An excitation coil assembly 40 of the driving mechanism, an enclosure 50 and a lower cover 60.

11, the upper mechanism assembly 20 includes a main circuit terminal 1, a first fixed contact 3-1 and a second fixed contact 3-2 as fixed contacts, A ferrite magnet 22, an upper cover 21, an insulating support, and the like.

FIG. 11 is a top view and a top view of the upper mechanism assembly 20 in the same manner as in the prior art to show the structure of the upper mechanism assembly 20. In assembly, the upper mechanism assembly 20 has an attitude as shown in FIG.

11, the main circuit terminal 1 is not visible due to the insulator support portions but is connected to the first fixed contact 3-1 and the second fixed contact 3- 2). In FIG. 11, a contact portion shown below the first fixed contact 3-1 and the second fixed contact 3-2 is a part of the conductor.

The first fixed contact 3-1 and the second fixed contact 3-2 are connected to one fixed contact connected to the positive electrode side main circuit terminal 1 and another fixed contact connected to the negative electrode side main circuit terminal 1 And are welded to the contact portions of the main circuit terminal 1, respectively.

The strong magnet 22 is constituted by a permanent magnet having a strong magnetic property, and an arc generated when the first fixed contact 3-1 and the movable contact 4-1 are separated from each other in a contact state, To the side of the first stationary contact 3-1 and the movable contact 4-1.

According to a preferred aspect of the present invention, the strong magnet 22 is provided only on the left and right sides of the first fixed contact 3-1, and the strong magnet 22 is installed around the second fixed contact 3-2 It does not. According to a preferred aspect of the present invention, only the first fixed contact 3-1 and the second fixed contact 3-2 contact or separate from the movable contact 4-1, which will be described later, This is because the second fixed contact 3-2 does not generate an arc since it is always electrically and mechanically connected to the first fixed contact 3-1 by the conductive connector 14. [

The upper cover 21 is a lid part for shielding the internal components of the relay according to the present invention from the outside and includes a lower cover 60 for shielding the lower part of the excitation coil assembly 40, The shield assembly 30-1 and the excitation coil assembly 40 located at the top and the middle of the relay are shielded from the outside.

The insulator support portion may be composed of a synthetic resin material having electrical insulation as a portion that electrically insulates and supports the inner side extension portion of the main circuit terminal 1 and the strong magnet 22 and the like.

The relay according to the present invention has a driving force which moves the movable contact 4-1 to a first position in contact with the first stationary contact 3-1 or to a second position in which it is separated from the first stationary contact 3-1, And a driving mechanism for providing the driving force.

12, the shaft assembly 30-1 included in the drive mechanism includes a shaft 5-1, a movable contact 4-1, a contact spring 7-1, And includes a core 15 and a movable core 10-1.

The shaft assembly 30-1 may further include a return spring 13-1.

The shaft 5-1 may be formed of an electrically insulating material having rigidity as a long cylindrical member.

The upper end of the shaft 5-1 is coupled to the movable contact 4-1 by welding or the like and the lower end of the shaft 5-1 is connected to the lower end of the shaft 5-1, And can be coupled with the movable core 10 by a connecting member.

The shaft 5-1 supports the movable contact 4-1 while coaxially coaxial with the movable contact 4-1 (see reference character A in FIG. 10) It is movable together.

The shaft 5-1 has a configuration that is coaxial with the movable contact 4-1 and supports the movable contact 4-1 and is movable together with the movable contact 4-1 (Refer to symbols a1 and a2 in Fig. 2) and the axis of the shaft (refer to a reference b in Fig. 2) are different from each other, the transmission of the driving force for moving the movable contact 4-1 Effect can be provided.

Also, in the coupled state, the shaft 5-1 and the movable core 10 can move integrally in the same direction.

The movable contact 4-1 is formed of a conductive material and the lower portion of the movable contact 4-1 is connected to the upper first fixed contact 3-1 so as to receive elastic pressure upward.

4, when the movable contact 4 and the movable contact 4a according to the prior art are supported by the contact spring 7 only and flow in the hollow portion of the shaft 5, Since the movable contact 4-1 according to a preferred embodiment of the present invention has a structure coupled with the shaft 5-1, there is no flow and the contact position with the first fixed contact 3-1 can be made constant do.

According to a preferred aspect of the present invention, the movable contact 4-1 is composed of a single contact unlike the prior art having a pair of contacts.

The movable contact 4-1 is movable to a first position where it contacts the first stationary contact 3-1 and a second position which separates from the first stationary contact 3-1.

10 or 12, the contact spring 7-1 is provided so as to apply an elastic force to the movable contact 4-1 in a direction to contact the first fixed contact 3-1, And has one end (upper end in the figure) contacting the movable contact 4-1.

10 or 12, the other end of the contact spring 7-1 may be supported by the upper yoke of the yoke 9, according to a preferred embodiment. The other end of the contact spring 7-1 may be supported by the upper surface of the movable core 10-1 and the upper surface of the movable core 10-1 may be supported by the contact spring 7-1 And the other end thereof.

The contact spring 7-1 may be composed of a compression coil spring. In particular, the upper end of the contact spring 7-1 is supported at the lower portion of the movable contact 4-1 and the lower end of the contact spring 7-1 Is supported by the upper yoke of the yoke 9 according to one embodiment as described above.

According to one embodiment, the contact spring 7-1 has a tapered shape in which the lower end of the contact spring 7-1 has a smaller diameter as it goes downward so that it can be supported by the through hole formed in the central portion of the upper yoke among the yokes 9 That is, a conical compression coil spring.

The fixed core 15 may be a cylindrical member formed of an electrically insulating material and has a central through-hole portion allowing a vertical penetration of the shaft 5-1 at a radial center portion, Has a lower spring support groove portion having a larger diameter than the central through-hole portion for supporting one end (the upper end in Fig. 10) of the return spring 13-1. The outer diameter of the return spring 13-1 is smaller than the diameter of the lower spring support groove portion of the fixed core 15 and larger than the central through hole portion of the fixed core 15. [

The role of the fixed core 15 according to the present invention is to determine the moving distance S of the movable core 10-1 during the turn-on operation of the relay according to the present invention, To support wealth.

The movable core 10-1 may be formed of a hollow cylindrical iron core.

A rubber pad may be inserted into the lower end of the movable core 10 to be coupled with the movable core 10 as in the prior art.

The rubber pad is caused by collision with the inner bottom surface of the enclosure 50 when the movable core 10-1 returns to its original lowered position by the return spring 13-1 in the element of the excitation coil assembly 40 Which may be provided to mitigate the impact noise and impact.

After inserting the lower portion of the shaft 5-1 into the hollow portion of the movable core 10-1, a pin is inserted horizontally into the lower portion of the movable core 10-1 and the shaft 5-1 The engagement of the movable core 10-1 and the shaft 5-1 can be accomplished by pressing both ends of the penetrating pin.

As described above, the movable core 10-1 connected to the lower portion of the shaft 5-1 is fixed to the stationary core 15-1 in accordance with the magnetization or demagnetization of the coil 6, which will be described later, of the excitation coil assembly 40 And to a position separated from the stationary core 15. The stationary core 15 is movable in a direction in which the stationary core 15 is moved.

That is, the movable core 10-1 is magnetized by a magnetic field from the excitation coil assembly 40 and is raised by a vertical magnetic field applied from the excitation coil assembly 40, or is excited by the excitation coil assembly 40 And is lowered by the elastic force of the return spring 13 which acts on the upper end of the shaft 5-1 when it is demagnetized.

The return spring 13-1 is installed between the fixed core 15 and the movable core 10-1 so as to be inserted into the inner diameter portion of either the fixed core 15 or the movable core 10-1 (In the embodiment shown in FIG. 10, inserted into the fixed core), and applies an elastic force to the movable core 10-1 in a direction separating from the fixed core 15.

The movable core 10-1 is provided with a driving force that overcomes the elastic force of the contact spring 7-1 and moves the movable core 10-1 so as to be separated from the fixed core 15 when the coil 6 is disengaged The elastic coefficient of the return spring 13-1 is greater than the elastic coefficient of the contact spring 7-1.

Meanwhile, the conductive connector 14 included in the relay according to the preferred embodiment of the present invention always keeps the movable contact 4-1 and the second fixed contact 3-2 in contact with each other And is provided as a means for electrical connection at all times.

According to a preferred embodiment of the present invention, the conductive connector 14 is connected to the movable contact 4-1 at one end and connected to the second fixed contact 3-2 at the other end COPPER WIRE (aka FLEXIBLE WIRE). As another embodiment, the interlocking wire may be replaced by a wire having a length that does not cause a problem in moving the movable contact 4-1, and the electrically conductive contact 14 may move the movable contact 4-1 while allowing movement of the movable contact 4-1. A conductive material which always electrically connects the first fixed contact 3-1 and the second fixed contact 3-2 can be replaced with another substitute.

One end and the other end of the conductive connector 14 can be connected to the movable contact 4-1 and the second fixed contact 3-2 by welding including spot welding, for example.

On the other hand, since the movable contact 4-1 and the second fixed contact 3-2 are always connected by the conductive connector 14, the movable contact 4-1 and the first fixed contact 3-2 The distance (insulation distance) between the movable contact 4-1 and the first fixed contact 3-1 in order to secure the insulation distance between the movable contact and the fixed contact in the above- Is formed to be twice as long as the spacing distance (insulation distance) according to the preferred embodiment.

The configuration of the exciting coil assembly 40 in the driving mechanism will be described with reference to Figs. 13 and 10. Fig.

The excitation coil assembly 40 includes a bobbin 8, a coil 6, a yoke 9 and a control signal receiving terminal 2 as shown in Fig. 13 or Fig. .

The bobbin 8 has a cylindrical body portion which is hollow inside to allow entry or departure of the movable core 10 as in the prior art and a cylindrical body portion formed at the upper and lower ends of the body portion to determine a winding limit of the coil 6 And a flange portion, and a coil (6) is wound on the body portion.

The coil 6 is wound on the body portion of the bobbin 8 and excited or magnetized depending on whether a control signal is applied to the control signal receiving terminal 2 or not.

According to the configuration change in which the insulation distance between the movable contact 4-1 and the first fixed contact 3-1 is longer than that in the prior art when the switch is in the OFF state, Lt; / RTI > Therefore, the size of the bobbin 8 must be larger than that of the prior art, and the amount of winding of the coil 6 wound on the bobbin 8 is also increased compared to the prior art.

The yoke 9 is formed so as to surround the outside of the bobbin 8 as best seen in Fig. 10, and provides a path for circulating the magnetic flux generated by the coil 6 when the coil 6 is excited.

According to one embodiment of the present invention, the stationary core 15 is welded to the bottom surface of the upper yoke of the yoke 9, for example, by laser welding, and is coupled to the yoke 9.

10 or 13, the control signal receiving terminal 2 is provided so as to pass through the coil 6 wound around the control signal receiving terminal 2. When receiving the control signal through the control signal receiving terminal 2, The coil 6 is excited, and when the control signal is stopped, the coil 6 is excited.

10 or 14, the enclosure 50 provides a means for housing the components of the relay 100 according to the present invention, and may be formed of a synthetic resin material having electrical insulation. 14, the enclosure 50 may be formed of a rectangular box-like member whose one side is opened and the inside is empty and the remaining five sides are closed to accommodate parts.

14, the lower cover 60 is a lid portion for shielding the internal components of the relay 100 from the outside, and includes an upper mechanism assembly 20 located at the upper portion and the intermediate portion of the relay 100, Unlike the upper cover 21 which shields the assembly 30 from the outside, the lower portion of the excitation coil assembly 40 located below the relay 100 is shielded from the outside.

The lower cover 60 has two through-holes correspondingly formed to allow penetration for exposure of the control signal receiving terminal 2.

The operation of the relay 100 according to the preferred embodiment of the present invention will be briefly described.

When the control signal is applied through the control signal receiving terminal 2 in the OFF state of the relay 100 as shown in Fig. 10, the coil 6 is excited and the vertical magnetic field The movable core 10-1 is also energized to rise.

The shaft 5-1 to which the lower portion is coupled to the movable core 10-1 also overcomes the elastic force of the return spring 13-1 and moves upwardly so that the movable contact 4-1 supported by the shaft 5-1 -1).

The movable contact 4-1 rises to be in an ON state in which it contacts the corresponding first fixed contact 3-1, and this ON state is a state shown in Fig.

Then, from the positive main circuit terminal 1, the first fixed contact 3-1, the movable contact 4-1, the electrically conductive contact 14, the second fixed contact 3-2, The electric current path from the positive main circuit terminal 1 to the negative main circuit terminal 1 is formed and the DC power can be supplied through the relay 100 as the closed circuit to the main circuit terminal 1 is formed.

15, when the application of the control signal through the control signal receiving terminal 2 is stopped, the vertical magnetic field imposed from the coil 6 is removed while the coil 6 is disengaged, and the movable core 10-1 are also disengaged, the lifting driving force of the movable core 10-1 disappears.

The shaft 5-1 descends due to the elastic force of the return spring 13-1 acting on the upper surface of the movable core 10-1 and the movable contact 4-1 supported by the shaft 5-1 -1) also falls.

Therefore, the movable contact 4-1 is lowered and turned off from the corresponding first fixed contact 3-1, and this off state is the state shown in Fig.

Then, the energizing path from the positive main circuit terminal 1 to the negative main circuit terminal 1 is interrupted, and the DC power is stopped from being supplied through the relay 100. [

On the other hand, the electromagnetic repulsive force generated in the vicinity of the contact at the initial stage of the ON operation will be described with reference to FIG.

The current flowing through the first fixed contact 3-1 connected to the positive main circuit terminal as shown in the figure is again transmitted through the movable contact 4-1 and the conductive contact 14 through the second fixed contact 3- The movable contact 4-1 is connected to the first fixed contact 3-1 through the second fixed contact 3-1 because the direction of the incoming current I1 and the current direction of the outflow current I2 are opposite to each other, 1 is generated between the contact points but the second fixed contact point 3-2 is connected to the movable contact point 4-1 through the conductive connection member 14 so that the electromagnetic repulsion force is minimized compared to the prior art . At this time, a current flowing from the movable contact 4-1 to the second fixed contact 3-2 through the electrically conductive contact 14 is represented by I3.

The arc generated between the movable contact 4-1 and the first fixed contact 3-1 by the magnetic field B from the strong magnet 22 is subjected to a force pushing it outward like a force F1.

Therefore, as can be seen from FIG. 17, the CHATTERING phenomenon in which the initial movable contact contacts the fixed contact and is disconnected rapidly can be negligibly reduced.

As described above, since the relay according to the present invention includes the conductive connecting member that always electrically connects the movable contact to any one of the fixed contacts, the electromagnetic repulsion force is reduced during the closing operation (on operation) It is possible to provide an effect that can be remarkably reduced.

In the relay according to the present invention, since the movable contact is constituted by a single contact point, it is possible to prevent the phenomenon that only one of the contact points is biased in contact and the contact is unevenly worn, thereby improving the operation reliability of the relay It has the effect of extending the contact life.

1: Main circuit terminal 2: Control signal receiving terminal
3: fixed contact 3-1: first fixed contact
3-2: second fixed contact point 4: movable contact point
4a: movable contactor 4-1: movable contact
5: Shaft 5-1: Shaft
6: coil 7: contact pressure spring
7-1: Contact spring
8: Bobbin 9: York
10: movable core 10-1: movable core
11: rubber pad 12: steel magnet
13: return spring 13-1: return spring
14: conductive connector 15: fixed core
20: upper mechanism assembly 21: upper cover
22: Steel magnets
30: movable part assembly 30-1: shaft assembly
40: excitation coil assembly
50: enclosure 60: bottom cover
100: Relay

Claims (7)

In the relay,
A fixed contact having a first fixed contact and a second fixed contact;
A movable contact movable into a first position contacting the first stationary contact and a second position separated from the first stationary contact;
A conductive connector for electrically connecting the movable contact and the second fixed contact at all times; And
And a driving mechanism for providing a driving force to move the movable contact to the first position or the second position. The method according to claim 1,
And the movable contact is constituted by a single contact. The method according to claim 1,
The conductive connector
(FLEXIBLE COPPER WIRE) having one end connected to the movable contact and the other end connected to the second fixed contact. The method according to claim 1,
And a permanent magnet which is not installed around the second stationary contact but installed only around the first stationary contact to protect the contact from the arc. The method according to claim 1,
The drive mechanism includes:
A coil assembly including a coil for providing a driving force such that the movable contact is located at a first position when magnetized;
A stationary core fixedly installed in the coil assembly;
A shaft that is coaxial with the movable contact and supports the movable contact and is movable together with the movable contact;
A contact spring having one end contacting the movable contact so as to apply an elastic force to the movable contact in a direction in contact with the fixed contact; And
And a movable core connected to a lower portion of the shaft and movable to a position where the movable core approaches and separates from the fixed core according to magnetization or demagnetization of the coil. 6. The method of claim 5,
And the shaft is coupled to the movable contact to support the movable contact without flow. 6. The method of claim 5,
Further comprising a return spring inserted between the fixed core and the movable core so as to be inserted into the inner diameter portion of either the fixed core or the movable core and applying an elastic force to the movable core in a direction away from the fixed core Lt; / RTI >

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